Maintaining even and odd array pointers to extreme values by searching and comparing multiple elements concurrently where a pointer is adjusted after processing to account for a number of pipeline stages

ABSTRACT

In one embodiment, a programmable processor searches an array of N data elements in response to N/M machine instructions, where the processor has a pipeline configured to process M data elements in parallel. In response to the machine instructions, a control unit directs the pipeline to retrieve M data elements from the array of elements in a single fetch cycle, concurrently compare the data elements to M current extreme values, and update the current extreme values, as well as M references to the current extreme values, based on the comparisons.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional application of and claims priority to U.S. patent application Ser. No. 09/675,066, filed Sep. 28, 2000.

BACKGROUND

This invention relates to array searching operations for a computer.

Many conventional programmable processors, such as digital signal processors (DSP), support a rich instruction set that includes numerous instructions for manipulating arrays of data. These operations are typically computationally intensive and can require significant computing time, depending upon the number of execution units, such as multiply-accumulate units (MACs), within the processor.

DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram illustrating an example of a pipelined programmable processor.

FIG. 2 is a block diagram illustrating an example execution pipeline for the programmable processor.

FIG. 3 is a flowchart for implementing an example array manipulation machine instruction.

FIG. 4 is a flowchart of an example routine for invoking the machine instruction.

FIG. 5 is a flowchart for a single SEARCH instruction.

FIG. 6 is a flowchart where a software application issues N/M SEARCH instructions and, upon completion of the N/M SEARCH instructions, determines an extreme value for an entire array.

DESCRIPTION

FIG. 1 is a block diagram illustrating a programmable processor 2 having an execution pipeline 4 and a control unit 6. Processor 2, as explained in detail below, reduces the computational time required by array manipulation operations. In particular, processor 2 may support a machine instruction, referred to herein as the SEARCH instruction, that reduces the computational time to search an array of numbers in a pipelined processing environment.

Pipeline 4 has a number of stages for processing instructions. Each stage processes concurrently with the other stages and passes results to the next stage in pipeline 4 at each clock cycle. The final results of each instruction emerge at the end of the pipeline in rapid succession.

Control unit 6 controls the flow of instructions and data through the various stages of pipeline 4. During the processing of an instruction, for example, control unit 6 directs the various components of the pipeline 4 to fetch and decode the instruction, perform the corresponding operation and write the results back to memory or local registers.

FIG. 2 illustrates an example pipeline 4 configured according to the invention. Pipeline 4, for example, has five stages: instruction fetch (IF), decode (DEC), address calculation (AC), execute (EX) and write back (WB). Instructions are fetched from memory, or from an instruction cache, during the IF stage by fetch unit 21 and decoded within address registers 22 during the DEC stage. At the next clock cycle, the results pass to the AC stage, where data address generators 23 calculate any memory addresses that are necessary to perform the operation.

During the EX stage, execution units 25A through 25M perform the specified operation such as, for example, adding or multiplying numbers, in parallel. Execution units 25 may contain specialized hardware for performing the operations including, for example, one or more arithmetic logic units (ALU's), floating-point units (FPU) and barrel shifters. A variety of data can be applied to execution units 25 such as the addresses generated by data address generator 23, data retrieved from data memory 18 or data retrieved from data registers 24. During the final stage (WB), the results are written back to data memory or to data registers 24.

The SEARCH instruction supported by processor 2, may allow software applications to search an array of N data elements by issuing N/M search instructions, where M is the number of data elements that can be processed in parallel by execution units 25 of pipeline 4. Note, however, that a single execution unit may be capable of executing two or more operations in parallel. For example, an execution unit may include a 32-bit ALU capable of concurrently comparing two 16-bit numbers.

Generally, the sequence of SEARCH instructions allows the processor 2 to process M sets of elements in parallel to identify an “extreme value”, such as a maximum or a minimum, for each set. During the execution of the search instructions, processor 2 stores references to the location of the extreme value of each of the M sets of elements. Upon completion of the N/M instructions, as described in detail below, the software application analyzes the references to the extreme values for each set to quickly identify an extreme value for the array. For example, the search instruction allows the software applications to quickly identify either the first or last occurrence of a maximum or minimum value. Furthermore, as explained in detail below, processor 2 implements the operation in a fashion suitable for vectorizing in a pipelined processor across the M execution units 25.

As described above, a software application searches an array of data by issuing N/M SEARCH machine instructions to processor 2. FIG. 3 is a flowchart illustrating an example mode of operation 300 for processor 2 when it receives a single SEARCH machine instruction. Process 300 is described with reference to identifying the last occurrence of a minimum value within the array of elements; however, process 300 can be easily modified to perform other functions such as identifying the first occurrence of a minimum value, the first occurrence of a maximum value or a last occurrence of a maximum value.

For exemplary purposes, process 300 is described in assuming M equals 2, i.e., processor 2 concurrently processes two sets of elements, each set having N/2 elements. However, the process is not limited as such and is readily extensible to concurrently process more than two sets of elements. In general, process 300 facilitates vectorization of the search process by fetching pairs of elements as a single data quantity and processing the element pairs through pipeline 4 in parallel, thereby reducing the total number of clock cycles necessary to identify the minimum value within the array. Although applicable to other architectures, process 300 is well suited for a pipelined processor 2 having multiple execution units in the EX stage. For the two sets of elements, process 300 maintains two pointer registers, P_(Even) and P_(Odd), that store locations for the current extreme value within the corresponding set. In addition, process 300 maintains two accumulators, A0 and A1, that hold the current extreme values for the sets. The pointer registers and the accumulators, however, may readily be implemented as general-purpose data registers without departing from process 300.

Referring to FIG. 3, in response to each SEARCH instruction, processor 2 fetches a pair of elements in one clock cycle as a single data quantity (301). For example, processor 2 may fetch two adjacent 16-bit values as one 32-bit quantity. Next, processor 2 compares the even element of the pair to a current minimum value for the even elements (302) and the odd element of the pair to a current minimum value for the odd elements (304).

When a new minimum value for the even elements is detected, processor 2 updates accumulator A0 to hold the new minimum value and updates a pointer register P_(Even) to hold a pointer to point to a corresponding data quantity within the array (303). Similarly, when a new minimum value for the odd elements has been detected, processor 2 updates accumulator A1 and a pointer register P_(Odd) (305). In this example, each pointer register P_(Even) and P_(Odd) points to the data quantity and not the individual elements, although the process is not limited as such. Processor 2 repeats the process until all of the elements within the array have been processed (306). Because processor 2 is pipelined, element pairs may be fetched until the array is processed.

The following illustrates exemplary syntax for invoking the machine instruction: (P _(Odd) , P _(Even))=SEARCH R _(Data) LE, R _(Data) =[P _(fetch) _(—) _(addr)++]

Data register R_(Data) is used as a scratch register to store each newly fetched data element pair, with the least significant word of R_(Data) holding the odd element and the most significant word of R_(Data) holding the even element. Two accumulators, A0 and A1, are implicitly used to store the actual values of the results. An additional register, P_(fetch) _(—) _(addr), is incremented when the SEARCH instruction is issued and is used as a pointer to iterate over the N/2 data quantities within the array. The defined condition, such as “less than or equal” (LE) in the above example, controls which comparison is executed and when the pointer registers P_(Even) and P_(Odd), as well as the accumulators A0 and A1, are updated. The “LE”, for example, directs processor 2 to identify the last occurrence of the minimum value.

In a typical application, a programmer develops a software application or subroutine that issues the N/M search instructions, probably from within a loop construct. The programmer may write the software application in assembly language or in a high-level software language. A. compiler is typically invoked to process the high-level software application and generate the appropriate machine instructions for processor 2, including the SEARCH machine instructions for searching the array of data.

FIG. 4 is a flowchart of an example software routine 30 for invoking the example machine instructions illustrated above. First, the software routine 30 initializes the registers including initializing A0 and A1 and pointers P_(Eve) and P_(Odd) to the first data quantity within the array (31). In one embodiment, software routine 30 initializes a loop count register with the number of SEARCH instructions to issue (N/M). Next, routine 30 issues the SEARCH machine instruction N/M times (32). This can be accomplished a number of ways, such as by invoking a hardware loop construct supported by processor 2. Often, however, a compiler may unroll a software loop into a sequence of identical SEARCH instructions (32).

After issuing N/M search instructions, A0 and A1 hold the last occurrence of the minimum even value and the last occurrence of the minimum odd value, respectively. Furthermore, P_(Even) and P_(Odd) store the locations of the two data quantities that hold the last occurrence of the minimum even value and the last occurrence of the minimum odd value.

Next, in order to identify the last occurrence of the minimum value for the entire array, routine 30 first increments P_(Odd) by a single element, such that P_(Odd) points directly at the minimum odd element (33). Routine 30 compares the accumulators A0 and A1 to determine whether the accumulators contain the same value, i.e., whether the minimum of the odd elements equals the minimum of the even elements (34). If so, the routine 30 compares the pointers to determine whether P_(Odd) is less than P_(Even) and, therefore, whether the minimum even value occurred earlier or later in the array (35). Based on the comparison, the routine determines whether to copy P_(Odd) into P_(Even) (37).

When the accumulators A0 and A1 are not the same, the routine compares A0 to A1 in order to determine which holds the minimum value (36). If A1 is less than A0 then routine 30 sets P_(Even) equal to P_(Odd), thereby copying the pointer to the minimum value from P_(Odd) into P_(Even) (37).

At this point, P_(Even) points to the last occurrence of the minimum value for the entire array. Next, routine 30 adjusts P_(Even) to compensate for errors introduced to the pipelined architecture of processor 2 (38). For example, the comparisons described above are typically performed in the EX stage of pipeline 4 while incrementing the pointer register P_(fetch) _(—) _(addr) typically occurs during the AC stage, thereby causing the P_(Odd) and P_(Even) to be incorrect by a known quantity. After adjusting P_(Even), routine 30 returns P_(Even) as a pointer to the last occurrence of the minimum value within the array (39).

FIG. 5 illustrates the operation for a single SEARCH instruction as generalized to the case where processor 2 is capable of processing M elements of the array in parallel, such as when processor 2 includes M execution units. The SEARCH instruction causes processor 2 to fetch M elements in a single fetch cycle (51). Furthermore, in this example, processor 2 maintains M pointer registers to store addresses (locations) of [[ ]] corresponding extreme values for the M sets of elements. After fetching the M elements, processor 2 concurrently compares the M elements to [[ ]] current extreme values for the respective element sets, as stored in M accumulators (52). Based on the comparisons, processor 2 updates the M accumulators and the M pointer registers (53).

FIG. 6 illustrates the general case where a software application issues N/M SEARCH instructions and, upon completion of the instructions, determines the extreme value for the entire array. First, the software application initializes a loop counter, the M accumulators used to store the current extreme values for the M element sets and the M pointers used to store the locations of the extreme values (61). Next, the software application issues N/M SEARCH instructions (62). After completion of the instructions, the software application may adjust each of the M pointer registers to correctly reference its respective extreme value, instead of the data quantity holding the extreme value (63). After adjusting the pointer registers, the software application compares the M extreme values for the M element sets to identify an extreme value for the entire array, i.e., a maximum value or a minimum value (64). Then, the software application may use the pointer registers to determine whether more than one of the element sets have an extreme value equal to the array extreme value and, if so, determine which extreme value occurred first, or last, depending upon the desired search function (65).

Various embodiments of the invention have been described. For example, a single machine instruction has been described that searches an array of data in a manner that facilitates vectorization of the search process within a pipelined processor. The processor may be implemented in a variety of systems including general purpose computing systems, digital processing systems, laptop computers, personal digital assistants (PDA's) and cellular phones. For example, cellular phones often maintain an array of values representing signal strength for services available 360° around the phone. In this context, the process discussed above can be readily used upon initialization of the cellular phone to scan the available services and quickly select the best service. In such a system, the processor may be coupled to a memory device, such as a FLASH memory device or a static random access memory (SRAM), that stores an operating system and other software applications. These and other embodiments are within the scope of the following claims. 

1. An apparatus comprising: a processor coupled to a memory device, wherein the processor includes a pipeline configured to process M data elements in parallel and a control unit configured to direct the pipeline to search an array of N data elements for an extreme value in response to N/M machine instructions, wherein in response to the machine instructions, the pipeline being configured to: retrieve M data elements from the array of N data elements in a single fetch cycle; concurrently compare the retrieved M data elements to corresponding M current extreme values, and update accumulators and pointers associated with the M current extreme values based on said comparing, the pointers including one or more pointer registers to store information indicative of addresses of extreme values in the array of N data elements; and analyze results of the N/M machine instructions to identify at least a value of at least one extreme value in the array, wherein the at least one extreme value comprises an extreme value occurring more than once in the array, and wherein the position of the at least one extreme value in the array comprises a position of a predetermined one of a first occurrence and a last occurrence of the extreme value occurring more than once in the array.
 2. An apparatus as in claim 1, further comprising the memory device.
 3. An apparatus as in claim 2, wherein the memory device comprises static random access memory.
 4. An apparatus as in claim 2, wherein the memory device comprises FLASH memory.
 5. An apparatus as in claim 1, wherein the pipeline includes M registers configured to store the accumulators and pointers.
 6. An apparatus as in claim 5, wherein the registers include first and second pointer registers to store information indicative of addresses of first and second extreme values of the array.
 7. An apparatus as in claim 5, wherein the registers are general-purpose data registers.
 8. An apparatus comprising: a processor coupled to a memory device, wherein the processor comprises: a pipeline configured to process M data elements in parallel; a control unit configured to direct the pipeline to search an array of N data elements by issuing N/M search instructions; and M registers configured to store accumulators and pointers; wherein in response to the search instructions, the pipeline being configured to: store references to a location of a data element value for each of the M data elements; determine an array value based on the stored references to the data element values; update an accumulator to hold the array value; and update a pointer to reference data quantity corresponding to the array value.
 9. An apparatus as in claim 8, further comprising the memory device.
 10. An apparatus as in claim 9, wherein the memory device comprises static random access memory.
 11. An apparatus as in claim 9, wherein the memory device comprises FLASH memory.
 12. An apparatus for searching an array of N data elements for an extreme value, the apparatus comprising: means for issuing N/M machine instructions to a processor, wherein the processor is adapted to process M data elements in parallel; means for concurrently comparing M data elements to corresponding M current extreme values, means for retrieving another M elements in a single fetch cycle to be compared when executing a subsequent machine instruction; means for updating accumulators and pointers associated with the M current extreme values based on said means for concurrently comparing, the pointers including one or more pointer registers to store information indicative of addresses of extreme values in the array of N data elements; and means for analyzing results of the machine instructions to identify at least a value and a position of at least one extreme value in the array, wherein the at least one extreme value comprises an extreme value occurring more than once in the array, and wherein the position of the at least one extreme value in the array comprises a position of a predetermined one of a first occurrence and a last occurrence of the extreme value occurring more than once in the array.
 13. An apparatus as in claim 12, further comprising: means for determining an address of a first extreme value based on a value in a pointer register and based on a correction factor to compensate for one or more errors.
 14. An apparatus as in claim 12, further comprising: means for storing the M current extreme values in M accumulators; and means for copying the M data elements to the accumulators based on said means for concurrently comparing.
 15. An apparatus as in claim 12, wherein said means for concurrently comparing the M data elements to M corresponding current extreme values comprises means for determining whether each of the data elements is less than the corresponding current extreme value.
 16. An apparatus as in claim 12, wherein said means for concurrently comparing the M data elements to M corresponding current extreme values comprises means for determining whether each of the data elements is greater than the corresponding current extreme value.
 17. An apparatus as in claim 12, further comprising: means for setting up registers for said accumulators and pointers.
 18. An apparatus as in claim 12, wherein M=2 and N is greater than two.
 19. An apparatus as in claim 17, wherein said means for concurrently comparing the M data elements comprises means for processing a first data element with a first execution unit of a pipelined processor and means for processing a second data element with a second execution unit of the pipelined processor.
 20. An apparatus as in claim 17, wherein said means for concurrently comparing the M data elements comprises means for concurrently processing a first data element and a second data element within a single execution unit of a pipelined processor. 